1. A Coat Protein on Phagosomes Involved in the Intracellular Survival of Mycobacteria 
Giorgio Ferrari, Hanno Langen, Makoto Naito, Jean Pieters 
Cell 
Volume 97, Issue 4, Pages (May 1999)
DOI: /S (00)

2. Figure 1
Detection of a 50 kDa Protein Present in Phagosomes Containing Viable Mycobacteria
(a and b) Subcellular fractionation of phagosomes containing viable (a) and heat-killed (b) mycobacteria. The murine macrophage cell line J774 was infected for 1 hr with M. bovis BCG, followed by a 12 (live) or 2 (dead) hr chase, after which a homogenate was prepared. Organelles were subsequently separated by organelle electrophoresis, and the distribution of the organelle-specific markers as indicated were determined (upper panels). From each fraction, the amount of mycobacteria was quantitated by direct observation by light microscopy after acid fast staining (lower panels).
(c) Analysis of proteins present in subcellular fractions isolated from metabolically labeled macrophages. From infected macrophages (upper panels; left, live; right, dead), bacteria containing fractions after organelle electrophoresis were pooled and phagosomes were prepared by low-speed centrifugation as described in Experimental Procedures. Separately, from uninfected macrophages a late endosomal/lysosomal fraction as well as a lysosomal fraction (from pooling exclusively the most anodally β-hexosaminidase containing shifted membranes) was prepared by organelle electrophoresis and high-speed centrifugation (lower panels). Proteins from phagosomes were separated by two-dimensional IEF/SDS–PAGE and analyzed by fluorography. Acidic, left; basic, right. The 50 kDa protein specifically associated with phagosomes containing live bacteria is indicated by an arrow. The major spot in phagosomes containing viable mycobacteria represents actin.
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3. Figure 2 Identification of the 50 kDa Protein
(a) The polyacrylamide gel piece containing the 50 kDa protein (see Figure 1) was excised and subjected to lys-C digestion and mass spectrometry. Shown is the spectrum obtained after mass spectrometry.
(b) Predicted amino acid sequence of the 50 kDa protein. The five WD repeats present in the sequence are underlined.
(c) Immunoprecipitation using anti-TACO antibodies of cell lysates from metabolically labeled macrophages followed by two-dimensional IEF/SDS–PAGE. The gel was coelectrophoresed with different organelle fractions to allow alignment of the phagosomal 50 kDa spot (arrow).
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4. Figure 3 Distribution and Localization of TACO
(a) Tissue distribution of TACO. The different tissues as indicated were isolated from a mouse, homogenized, and total proteins (15 μg) separated by SDS–PAGE and immunoblotted using anti-TACO antiserum (upper panel). After stripping, the blot was reincubated with anti-actin antibodies (middle panel) or anti-tubulin antibodies (lower panel).
(b) Subcellular localization of TACO in uninfected cells. Macrophages were grown on coverslips, fixed, permeabilized, and stained for tubulin (upper left) followed by Texas red–labeled secondary antibodies or F-actin using phalloidin-Texas red (upper right) and double labeled for TACO using a rat monoclonal antibody followed by FITC-labeled secondary antibodies. (Lower left) Localization of actin (Texas red) and tubulin (FITC). (Lower right) Inclusion of the immunizing peptide blocked TACO staining. Bar, 5 μm.
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5. Figure 4 Subcellular Localization of TACO in Infected Cells
Macrophages were grown on coverslips and infected with live (a) or heat-killed (b) M. bovis BCG expressing the green fluorescent protein (BCG-GFP) for 1 hr followed by a chase for the times indicated. After fixation and permeabilization, the cells were stained for TACO using mAb GK3 followed by Texas red–labeled secondary antibodies. For each field, a bright field image is shown (left side). Bar, 5 μm. (c) For quantitation, cells were scored for the presence of TACO at the mycobacterial phagosome. Shown are mean values (± SD) from three experiments (n = 50). In (d), cells were infected with live (left) or heat-killed (right) mycobacteria followed by fixation and staining using anti-tubulin antibodies and Texas red–labeled secondary antibodies. Bar, 5 μm.
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6. Figure 5 Effect of Rifampicin and Alkalinization on TACO Distribution
(a) Cells were infected for 1 hr with live mycobacteria, followed by a 2 hr chase in the absence (upper panels) or presence (lower panels) of rifampicin (1 mg/ml), fixed, and stained for TACO as described. Quantitation of TACO recruitment (as in Figure 4) revealed a strong reduction of TACO colocalization with mycobacteria (right side). The difference in TACO recruitment between phagosomes containing heat- and rifampicin-killed mycobacteria might be due to differences in bacterial treatment.
(b) Cells were alkalinized as described in Experimental Procedures and subsequently infected with live (upper panels) or heat-killed (lower panels) mycobacteria for 1 hr, followed by a 2 hr chase. After fixation, cells were stained for TACO as described. Quantitation (right side) revealed that whereas ∼90% of the phagosomes containing viable bacilli had recruited TACO, virtually none of those containing killed bacilli colocalized with TACO. Bar, 5 μm.
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7. Figure 6 TACO Expression and Mycobacterial Entry in Liver Macrophages
(a and b) Localization of mycobacteria in TACO-negative Kupffer cells. (a) Kupffer cells were isolated from liver as described in Experimental Procedures, lysed, and total proteins (10 μg) separated by SDS–PAGE followed by immunoblotting using anti-TACO antibodies. As a control, a J774 lysate (10 μg) was used. (b) Isolated Kupffer cells were incubated for 1 hr with M. bovis BCG expressing the green fluorescent protein (BCG-GFP). Cells were washed and incubated for 2 hr (upper panels) or 16 hr (lower panels) prior to fixation and staining for lysosomal glycoprotein followed by Texas red–labeled secondary antibodies (LAMP-TR). Bar, 5 μm.
(c and d) Immunohistochemistry of TACO expression in mouse liver. Mice were untreated (c) or infected (d) with M. bovis BCG, sacrificed, and sections were obtained from the liver. Immunohistochemistry was performed using the rat mAb GK3 followed by HRP-coupled secondary antibodies (left panel), or double labeling was performed using mAb GK3 and Ziehl-Neelsen staining.
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8. Figure 7
Differential Trafficking and Survival of Mycobacteria in TACO-Transfected Cells
Mel JuSo cells transfected with cDNA encoding TACO in the sense (“TACO-transfected”) or antisense (“Control”) orientation were lysed and total proteins (10 μg) separated by SDS–PAGE followed by immunoblotting using anti-TACO antibodies (a). Control (b) or TACO-transfected (c) cells were incubated with mycobacteria for 1 hr followed by a 3 hr chase, homogenized, and subjected to organelle electrophoresis, and the distribution of the organelle-specific markers as indicated was determined (b and c, upper panels). From each fraction, the amount of mycobacteria was analyzed by direct observation by light microscopy after acid fast staining (b and c, lower panels). Shown is a representative experiment out of three. (d) TACO-transfected or control cells were infected with metabolically labeled mycobacteria for 1 hr at 37°C, washed, and lysed, and the total uptake was determined by liquid scintillation counting of the lysate. (e) TACO-transfected or control cells were incubated with mycobacteria, washed, and chased. At the chase times indicated, cells were lysed in PBS containing 0.5% Triton X-100, and bacteria were collected by centrifugation and resuspended in 7H9 medium. Serial dilutions were plated out and the number of colonies determined from the appropriate dilution. Shown are mean values (± SD) from five experiments (d and e).
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9. Figure 8
Model Describing the Role of TACO in Intracellular Survival of Mycobacteria
Phagocytosis triggers the recruitment of TACO (yellow) around the particle to be ingested, possibly as a result of its initial association with microtubules (black lines) at the cell cortex. In the case of viable bacteria (violet), TACO is actively retained on the phagosomal membrane, while it dissociates from the microtubule network, perhaps as a consequence of a conformational change. In contrast, during phagocytosis of killed bacteria (black) or after in situ killing of the bacilli, TACO initially associates with phagosomes but is rapidly released concomitant with lysosomal delivery of the bacilli.
Cell  , DOI: ( /S (00) )